EA001018B1 - Screw for fastening metal or plastic sections or plates onto a base - Google Patents

Abstract

1. A screw for fastening metal and/or plastic sections or plates to a substructure, comprising a shank with a threaded portion and a drive portion for applying a driving device, characterized in that the portion (6) of the shank (2) adjacent to the drive portion (3) flares toward the drive portion (3) conically, in the manner of a stepped cone or following a curve as viewed in cross section, and in that the diameter (DK) of the end of the flaring portion (6) of the shank (2) close to the drive portion is larger than the diameter (D2) of the borehole (14) receiving the screw (1) in the section (10) to be fastened and thus is also larger than the core diameter (D1) of the threaded portion (5) of the screw (1). 2. A screw according to claim 1, characterized in that the flaring portion (6) of the shank (2) extends directly to the drive portion (3) or to the underside (7) of the drive portion (3) formed as the screw head. 3. A screw according to claim 1, characterized in that the diameter (DK) of the end of the flaring portion (6) of the shank (2) close to the drive portion is larger than the outside diameter (DG) of the threaded portion (5) on the shank (2). 4. A screw according to one of claims 1 to 3, characterized in that the drive portion (3) comprises two regions (27, 28) disposed successively in axial direction with different structures for a tool drive. 5. A screw according to claim 4, characterized in that one region (27) of the drive portion (3) is designed for engagement of the driving tool and the other region (28) is designed for application of a tool for reverse rotation of the screw (1) if necessary, wherein a predetermined breaking point (29) acting as a stripping safeguard is formed between the two regions (27, 28) of the drive portion (3). 6. A screw according to claim 1, characterized in that the end of the shank (2) facing away from the drive portion (3) is constructed as the boring part (4). 7. A screw according to claim 1, characterized in that the end of the shank (2) facing away from the drive portion (3) is constructed as the penetration point (30) which self taps the borehole. 8. A screw according to claim 1, characterized in that the threaded region (5) of the shank (2) is of double-threaded construction. 9. A screw according to claim 1, characterized in that the threaded region (5) of the shank (2) is formed with a self-cutting thread. 10. A screw according to claim 8 or 9, characterized in that the threaded region (5) of the shank is constructed in the manner of an orbiform curve, for example with trilobular shape. 11. A screw according to one of claims 1 to 3, characterized in that the flaring portion (6) is trumpet-shaped. 12. A screw according to one of claims 1 to 3, characterized in that the flaring portion (6) is bell-shaped. 13. A screw according to one of claims 1 to 3, characterized in that the flaring portion (6) has the shape of a truncated cone. 14. A screw according to one of claims 1 to 3, characterized in that the drive portion (3) for a driving device is designed directly as an internal drive in the flaring portion (6) of the shank (2). 15. A screw according to claim 1 and any of the preceding claims, characterized in that the flaring portion (6) is provided on its surface with projections and/or depressions, with ribs (31), grooves, knurlings or the like.

Description

The invention relates to a screw for fastening metal and / or plastic profiles or plates on the supporting structure, consisting of a rod with a threaded section and a section of application of force screwing device.

It is when fixing profiles or plates on the supporting structure that problems arise in the sense that they need to be fixed in a state that is firmly pressed to the supporting structure. If the relatively rigid profiles or plates are additionally warped or have a longitudinal twist, then these negative impacts are further enhanced. In this case, as a rule, it is impossible to work with a stop that limits the depth on a screwdriver. Even when using torque clutches, problems arise with the moment of disconnection, since the torque after the screw head fits to the fixed profile increases accordingly and, thereby, causes the screwing device to turn off. The termination of the screwing movement then takes place regardless of whether the metal and / or plastic profile to be fixed or the plate is attached to the supporting structure or not.

The present invention has therefore posed the task of creating a screw of the type described above, in which a fastened profile or a fixed plate in a finally installed state fits snugly to the supporting structure and torque-dependent disconnection of the screwing device is ensured.

According to the invention, this is achieved due to the fact that the rod section adjacent to the area of application of the force expands in the direction of the area of application of force conically, stepped conically or, when viewed in cross section, repeating the shape of a certain curve, and that the diameter of the end of the extending section the rod is larger than the diameter of the screw hole drilled in the fastened profile and, thus, larger than the diameter of the core of the screw thread.

These measures, according to the invention, already when screwing the screw on one or several turns, cause tension of the fixed metal and / or plastic profile in the direction of the supporting structure and, thereby, pressing it to it. The expanding section of the rod due to the corresponding friction in the drilled hole and due to the expanding implementation in the direction of screwing causes a force on the fixed profile.

At the same time, it is easy to adjust the corresponding torque clutch with the possibility of its disengagement only at a correspondingly large torque. However, at this point in time, the fixed profile due to the action of the expanding section is already tightly pressed to the supporting structure, so it is only a matter of turning off the screwing device when the corresponding torque is reached. Torque is achieved due to the strong friction of the expanding area against the wall of the drilled hole. In this way, fast, torque-dependent tripping and the corresponding reliable prevention of further screwing in is possible.

The impact of the expanding area on the wall of the drilled hole additionally causes an extremely reliable fixation from unscrewing. The surface of the expanding area is with the wall of the drilled hole almost in a fit with a fit, and, moreover, it is with respectively warped or twisted profiles that the latter tend to return to their original position. As a result, an additional spring load constantly acts on the screw, which strengthens the fixation from unscrewing, especially taking into account the impact of the expanding section.

It is clear in itself that the expanding section must start from the rod or from its threadless section, since this expanding section should be simply inserted into the hole drilled in the profile to be fixed following the rod. This, however, requires that the expanding section, if possible, quickly and efficiently engage with the wall of the hole, in order to thereby ensure an axial tension in an optimal way. Consequently, in a relatively short section of the screwing path, the tightening torque and, thus, the axial tension, act on the fastened profile before the screw screwing process is finally completed.

The expanding section also provides the possibility of optimal fixing on the supporting structure even when it is made, if necessary, from thin sheet steel, other thin materials or from a material of low strength, for example, aerated concrete or foam plastic. Since the expanding section is a practically uncoupling element with a corresponding increase in torque, this prevents the thread from twisting in the supporting structure.

According to the invention, it is further provided that the expanding section of the rod comes directly to the area of application of force or to the underside of the area of application of force, made in the form of a screw head. This ensures continuous expansion of the hole until the final installation of the screw. Due to this, there is also a continuously increasing torque, which can be perceived by a screwdriver with an adjustable shutdown response, or otherwise further screwing in of the screw can be prevented.

It should also pay special attention to the fact that the disconnection due to the torque should occur very precisely, because if the switch is too late, under certain circumstances damage to the threaded engagement in the supporting structure may occur, so that the fastening itself will no longer act.

Further, it is preferable if the diameter close to the site of application of the force of the end of the expanding rod section is larger than the outer diameter of the threaded rod section. Whether there is a pre-drilled hole in the fastened profile or plate or a threaded hole into which the screw is screwed does not matter for the optimal effect of the present invention. The expanding section always causes axial tension in the threaded hole of the fixed profile or in a larger hole with respect to the thread diameter, respectively. In the presence of threads, they are again crushed or flattened by the expanding section, whereby the friction of the expanding section against the wall of the hole, at least at the first revolutions, is even smaller than if the wall of the hole were smooth. Consequently, in this case the corresponding tightening of the fixed profiles or plates with the bearing structure is ensured, before the screwing device is disconnected and, accordingly, the process of further screwing in the screw is interrupted.

The preferred implementation occurs when the area of application of the force is formed by two successive axes in the axial direction, differently made zones for engaging the tool. Therefore, depending on the need, it is also possible to tighten with a wrench with a larger or smaller throat and, thus, with a greater or lesser transmission of torque.

In this regard, another preferred implementation occurs when one zone of the force application area is made to engage the screwing device, and another area for installing the tool for possible unscrewing of the screw, with the place of weakened strength between the two zones of the force application area acting as a latch safety device. . This creates the possibility of screwing in with a single zone of the force application area, and after appropriate tightening of both interconnected parts and due to a corresponding increase in torque when the expanding shaft section engages, the torque increases so much that this first zone of the force application section breaks off. This suddenly prevents further screwing in of the screw, which prevents twisting in the supporting structure, in particular if it has a small thickness and / or small strength. However, however, when loosening, if necessary, a threaded joint, there is an additional zone of application of the force in which another tool can be installed.

The preferred implementation is that facing the site of application of force end of the rod is made in the form of a drilling part. Such an embodiment is preferable, in particular, when both parts to be interconnected do not have a greater thickness or when a corresponding hole has already been drilled in the part to be fixed on the supporting structure. In this case, the screw itself should only drill a hole in the supporting structure.

Just when two small parts of small thickness must be connected to each other, you can also perform the end of the rod facing away from the area of application of force in the form of a self-shaping hole penetrating the tip. Such constructive implementation is advisable, in particular, when, for example, aluminum or plastic parts must be connected to each other.

If relatively quick screw installation is required, it is preferable that the threaded portion of the rod is double threaded. Also, with a relatively fast axial feed of the screw, the location of the expanding section and precisely in connection with the place of weakened strength in the zone of application of force creates the optimal solution.

In order to avoid an excessive increase in torque even during the manufacture of a thread in the drilled hole, it has been proposed to perform a threaded rod section with a self-tapping thread. Thanks to this arrangement, the thread is manufactured with a relatively low torque, which eliminates the danger of too early shutdown or too early destruction of the weakened strength. In this regard, it is especially advisable if the threaded portion of the rod is made in the form of an equidistant profile, for example, trilobular. It turned out that such a thread is preferably when used in the supporting structure of small thickness and / or low strength.

Depending on the special fastening of metal and / or plastic profiles or plates on the supporting structure and depending on the material of the supporting structure, you can influence the torque set to turn off the screwing device or destroy the weakened strength. Thus, it is possible to perform an expanding area in the form of a funnel or cup-shaped implementation.

The simplest implementation in this regard occurs when the expanding section is made in the shape of a truncated cone. In this case, the penetration depth of this section can be preset by selecting the angle of the cone, and, in addition, depending on the angle of the cone, smaller or larger mutual friction surfaces are formed between the drilled or threaded hole and the surface of the truncated cone-shaped portion.

Another advantage of the invention is that the area of application of force for the screwing device is made directly in the form of an internal engagement zone in an expanding segment of the rod. It is also possible to envisage the area of application of force not in the form of a conventional screw head, but so that the screw ends with this expanding section.

Another possibility of influencing the friction between the expanding section and the surface of the drilled hole interacting with it occurs when the expanding section is provided with elevations and / or recesses, ribs, grooves, knurling, etc. on its surface. Due to this, it is possible to significantly increase or change the friction without reducing the effect of tightening between the fixed profile or plate and the supporting structure. This additional structuring of the surface of the expanding portion also causes an additional improvement in terms of fixation from unscrewing, in particular in the fixing points subject to vibrations or constant load changes.

The invention is explained in more detail below using the drawings, which depict:

FIG. 1 is a general view of one execution of a screw according to the invention;

FIG. 2 - an example of the use of such screws, partially in section;

FIG. 3 is an enlarged fragment of X in FIG.

2;

FIG. 4 - in perspective, an application option when securing the profiles of FIG. 2;

FIG. 5 - another form of execution of the screw; FIG. 6 shows a section along the line U1-U1 of FIG. five; FIG. 7-11 - other embodiments of the screw according to the invention;

FIG. 12-14 - two options for the implementation of the screw, interacting with the plate additional details.

The screw 1 according to the invention consists of a rod 2 and a force application section 3, made, for example, in the form of a screw head. The rod 2 has at its one end a drilling section 4 and is also provided with a threaded section 5. The section 6 of the rod 2 adjacent to the application section 3 is made with a tapered expansion in the direction of the application section 3 of force.

Below we are talking only about the conically expanding section 6, and the implementation of this section 6 may well be different. Along with the conic embodiment shown here, it is also possible to use a stepwise conic implementation or expansion, which in the section follows the shape of a certain curve. These embodiments are explained in more detail with the help of figures.

The conical section 6 of the rod 2 passes directly to the lower side 7 of the section 3 of the application of force. The diameter ΌΚ of the end of the conical section 6 close to the screw head is larger than the diameter Ό2 drilled in the fixed profile 10 of the hole 14 for the screw 1. Accordingly, the diameter is also larger than the diameter of the drilling section 4. To achieve the corresponding optimum effect, the diameter of the screw close to the head the end of the conical section 6 is larger than the outer diameter of the threaded section 5 of the rod 2. The screw 1 serves to secure the profiles 1 0 and, if necessary, the gaskets 10 'on the supporting structure 11, as can be seen, for example, from FIG. 3

For a more detailed explanation of the depicted special case of fastening, refer also to FIG. 4. Steel sheets 22 of trapezoidal section are laid on the beam 21 and are firmly connected to it. After placing the vapor barrier 23, the profiles 10, if necessary, are fixed with spacers on the sheet 22 through the gaskets 1 0 '. These sheets have a small thickness, so it is in this case that it is very important not only to firmly press and firmly hold the profile 10 on the supporting structure , but the fact that the screw was not twisted during the installation, i.e., that the thread remained firmly hooked on a very thin sheet 22. After installation of the profiles 10, heat insulation 24 is placed and, in conclusion, metal or plastic roofing is placed on it vertical folds. The connection of the plates 25 with vertical folds with the supporting structure formed by the sheet 22 is carried out by means of profiles 1 0, so that they are subject to particular load when the suction caused by the wind results.

With this type of fastening, it is important that it is not about the exact depth of installation of the screw 1, which can be seen from FIG. 2 and 3. Here, the process of further screwing in screw 1 is interrupted before the lower side 7 of the application section 3 of the force fits to the upper side 26 of the profile 10. It is in this application that this construction is preferable, since after this thermal insulation 24 is laid, so that in relation to the speakers for the upper side of the profile of the 10 parts of the screw 1 there are no problems. The execution of the screw 1 in FIG. 13, the expanding section 6 of the rod 2 passes directly to the section 3 of application of force and, thus, to the lower side 7 of section 3 of application of force, made in the form of a screw head. It is also possible that the conical section 6 does not pass directly to the lower side 7 of the application section 3 of a force made in the form of a screw head, but to, for example, a short cylindrical section adjoining this conical section 6, which then goes to the lower side 7 of the application section 3 force, made in the form of a screw head.

Particular implementation of the area 3 of the application of force is also evident from the figures. The force application area 3 is formed by two axes 27, 28 that follow one another in the axial direction and are made differently for engaging with the tool. In this case, the zone 27 of the force application portion 3 is made to engage the screwing device. Another zone 28, which in the depicted example of execution has a large outer periphery than zone 27, serves to install the tool with the aim of possibly unscrewing the screw 1 if necessary to loosen the connection. Between the two sections 27, 28 is made the place 29 of weakened strength. At least, there is an appropriate concentration of stresses in the transition from a thinner material to a thicker one, in order to ensure due to this fixation from twisting. When the conical section 6 is adjacent to the wall of the drilled hole 14 and when due to pressing the connected parts together and, thereby, due to pressing the conical section 6, a correspondingly high torque is achieved, the zone 27 of the force application section 3 breaks off, which suddenly prevents further screwing screw 1. Thus, there can be no twisting of the thread in the supporting structure 11, which is made, as a rule, of a material of small thickness or small strength.

Constructive implementation of both zones 27, 28 or between them weakened strength 29 can, of course, be different. It is quite possible to attract for screwing in the screw zone 28 of the area of application of force and separate it from the adjacent area 6 with the seat 29 of weakened strength. In this case, instead of the protruding zone 27, it is also possible to envisage as an internal engagement zone a corresponding zone which enters the conical section 6. Thus, there would be an external engagement zone for screwing, and an internal engagement zone for unscrewing. Moreover, it is also possible for the uppermost zone of the conic section 6 to be provided with a corresponding engagement zone for the key, i.e. would have a similarity 28, which, however, does not stand for the periphery of the conical section 6. In this connection, therefore, a number of constructive options are possible.

In various embodiments, according to the drawings, the end of the rod 2 facing away from the application section 3 is designed as a drilling part 4. Such an implementation is expedient, in particular, when relatively thin parts are to be connected to each other or when the part to be fixed is already pre-drilled. In this case, it is possible to do with a relatively short drilling part, since the drilling process must be completed before the threaded portion engages.

It is in the embodiment of FIG. 11 that the screw 1 can also be made with a penetrating tip 30 self-shaping the aperture. This embodiment is chosen when both the profile 1 0 and the supporting structure 11 have a relatively small thickness and are preferably made of aluminum or plastic.

The threaded section 5 of the rod 2 can be made single or multiple. In the case of multisubstituting, it is preferable to provide for two-way execution, and this, in particular, is taken into consideration when value is given to relatively quick installation.

Preferably the threaded portion of the rod is made with self-cutting thread. Due to this, the torque is not too high already when tapping, so the destruction of the weakened strength or the torque-dependent shutdown of the screwing device due to a sharp increase in torque occurs only when it is the conical section 6 that is used. threaded section 5 in the form of an equidistant profile, for example in trilobular execution.

As already mentioned, the expanding portion 6 can be performed in different ways. FIG. 8, the expanding portion 6 is made cup-shaped, so that the insertion angle of the portion 6 is first relatively flat, and then it becomes steeper. In contrast, the expanding portion 6 in FIG. 9 is made in the form of a track, so that the insertion angle of the section 6 with respect to the middle axis of the screw 1 is continuously increased. Thus, additionally, a fit of the applied torque can occur.

The simplest execution of the expanding section 6 occurs when it has the shape of a truncated cone, as can be seen from most of the depicted examples.

In the embodiments of FIG. 10, 11, 14 and 15 to the conical section 6 does not adjoin any additional special zone of the area of application of force. Here only a plot of application of force is provided in the form of an internal engagement zone 20.

FIG. 5 and 6 depict a variant in which the expanding section 6 is made in the form of a polygonal truncated pyramid, due to which elevations and / or depressions appear that serve to increase the friction when screwing in section 6 into the corresponding drilled hole.

The embodiment according to FIG. 7 has ribs 31 or grooves to increase friction, as well as increased fixation from unscrewing.

Within the framework of the invention, it is also possible to provide for elevations and / or recesses, ribs, grooves or, for example, knurling and the like. Further, various forms of cross-section are possible in the area of section 6. Thus, a section can be made in a section that is also non-circular, for example, ellipsoidal, or in the form of an equidistant profile, for example, trilobular.

From FIG. 12 that the screw according to the invention is particularly suitable also for use in a material of low strength. For example, in this way it is quite possible to fix in porobeton or in foam plastic without twisting the threaded portion in the supporting structure 11, despite sufficient fixing.

From the embodiment of FIG. 1 3 it can be seen that with a very strong tension or with the corresponding twisting of the profile 10, a gap 32 may appear between the profile 10 and the supporting structure 11.

However, in this, in itself, undesirable place of fastening is always, nevertheless, fixing the screw. With a corresponding load on the profile 10 in the direction of arrow 33, i.e., for example, with a corresponding suction load due to wind exposure, the profile 1 0 respectively pulls up and gets even more wedged, thus, relative to section 6. This creates an additional strengthening of fixation from unscrewing.

In the embodiment of FIG. 14, the profile 10 or the corresponding plate in the form of insulation, closed on both sides by sheets, is fixed on the supporting structure 11. The threaded section 5 of the screw 1 enters the supporting structure 11, and the expanding section 6 is pressed against the outer side of the profile 1 0, increasing the friction in the hole. Consequently, such fixing can be carried out without the necessity of a snug fit of the screw head or the underside of the screw head to the surface of the profile 1 0.

Another embodiment is shown in FIG. 1 5 and 1 6. In this embodiment, for example, the profile 10 and the supporting structure 11 are connected between each other, and on the profile 1 0 they establish a similarity of the profiled washer 35 held in the process of screwing in the screw with fixation against turning. By screwing in the threaded section 5, the profile 1 0 and the supporting structure 11 are pressed against each other as soon as section 6 comes into contact with the funnel-shaped inner surface 36 of the washer 35. Here too, a corresponding tightening occurs, and, in addition, corresponding friction occurs due to the expanding section 6, in order to disengage the torque clutch from the screwing device or cause the breaking off of the zone of the section 3 of the application of force. In the embodiment of FIG. 1 5 there is only an internal engagement zone 20, whereas in the embodiment of FIG. 1 to 6, the force application portion 3 is made in a similar manner as in FIG. one .

In very special cases, the force application section 3 may be provided on its lower side 7 with additional elevations and / or recesses. Here ribs, grooves, wavy ribs, notches, individual tips, sawtooth ribs, etc. can be made. Such an implementation would be advisable when the fixed profile or the fixed plate is made of a material of low strength, so that the expanding portion is fully drawn into the fixed profile or fixed plate under certain circumstances. The screwing device would then be turned off almost only at the very last moment in time and with a sudden maximum load of torque. Also here you can get by the torque clutch with mechanical, electronic or hydraulic control device.

Thanks to the measures according to the invention, the corresponding tightening torque always occurs when viewed in the axial direction of the screw, so that the fastened profile or the fastened plate always reliably and firmly pressed against the solid supporting structure

11. In addition, it is precisely due to the mutual tightening as a result of the fit of the expanding section 6 a sharp increase in torque occurs, which promptly causes a torque-dependent shutdown of the screwing device or the breaking off of the fastening element in the zone of weakened strength. Even in the case when axial forces do not occur due to mutual tightening of the fastened parts, a sufficiently strong increase in torque can be achieved due to the corresponding pressure on the fastener coming out, for example, from a screw-in device. A strong increase in torque when entering an expanding section reliably ensures that the screwing device is turned off before possible thread damage occurs in the supporting structure, so that the screw according to the invention can be used not only in the preferred manner in thin sheets, but also in a supporting structure made of thin material or material of low strength. In addition, an appropriate fixation against unscrewing is always guaranteed.

Claims (15)

1. A screw for fixing metal and / or plastic profiles or plates on a supporting structure, consisting of a rod with a threaded section and a force application section of a screwing device, characterized in that a section (6) of the rod (2) adjacent to the force application section (3) expands in the direction of the force application section (3) conically, stepwise conically or, if viewed in cross section, repeating the shape of a certain curve, while the diameter (ΌΚ) of the end force of the expanding section (6) of the rod (2) close to the application section (3) is larger diameter and (Ό2) drilled in a dockable profile (10) of the opening (14) the screw (1) and, thus, greater than the diameter (Ό1) threaded portion of the core (5) of the screw (1). 2. The screw according to claim 1, characterized in that the expanding section (6) of the rod goes directly to the section (3) of the application of force or to the lower side (7) of the section (3) of the application of force, made in the form of a screw head. 3. The screw according to claim 1, characterized in that the diameter (ΌΚ) of the end force of the expanding section (6) of the rod (2) close to the area (3) is larger than the outer diameter (IO) of the threaded section of the rod (2). 4. A screw according to one of claims 1 to 3, characterized in that the area (3) of application of force is formed by two axial successive successive zones made differently (27, 28) to engage the tool. 5. A screw according to claim 4, characterized in that the area (27) of the force application section (3) is made to engage the screwing device, and the zone (28) is used to install the tool with the aim of unscrewing the screw (1), and between both zones (27, 28) of the force application section (3), a place (29) of weakened strength, acting as a twist guard, is made. 6. The screw according to claim 1, characterized in that the end of the shaft (2) facing away from the force application section (3) is made in the form of a drilling part (4). 7. The screw according to claim 1, characterized in that the end of the rod (2) facing away from the force application section (3) is made in the form of a penetrating tip self-forming hole (30). 8. The screw according to claim 1, characterized in that the threaded section (5) of the rod (2) is made two-way. 9. The screw according to claim 1, characterized in that the threaded section (5) of the rod (2) is made with a self-tapping thread. 10. A screw according to claim 8 or 9, characterized in that the threaded portion (5) of the rod is made in the form of an equidistant profile, for example, trilobular. 11. The screw according to one of claims 1 to 3, characterized in that the expanding section (6) is made in the form of a funnel. 12. The screw according to one of claims 1 to 3, characterized in that the expanding section (6) is made bowl-shaped. 13. The screw according to one of claims 1 to 3, characterized in that the expanding section (6) is made in the form of a truncated cone. 14. The screw according to one of claims 1 to 3, characterized in that the force application section (3) for the screw-in device is made directly in the form of an internal engagement zone in the expanding section (6) of the rod (2). 15. The screw according to claim 1 and one of the preceding paragraphs, characterized in that the expanding section (6) is provided on its surface with elevations and / or recesses, ribs (31), knurling, etc.